An electronic camera apparatus reads out, from an image sensing device, an image signal which represents a color image constructed by a number of pixels to which predetermined colors are assigned and has pieces of luminance information with analog values representing luminances of the pixels, the luminance information being discrete on a time axis, and generates a desired image from the image signal. The apparatus has a luminance correction section.
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9. An electronic camera apparatus with the capability of correcting luminance balance in an image signal read out from an image sensing element, said image signal representing a color image constructed by a plurality of pixels and generating a desired image from the image signal, comprising:
a luminance correction section coupled at the output of the image sensing element and operative on individual units of raw colors of said pixels, each one of said pixels each being formed from a set of predetermined units of colors and each unit of color having an analog value representing luminance information, the luminance information being discrete on a time axis, to
A) generate individual correction coefficients for each of said predetermined colors of each said pixel from a plurality of correction coefficients
B) correct white balance using corresponding luminance information in the image signal on the basis of each said correction coefficient, and
C) output a new image signal used for image generation; and
D) store the new image in a memory located within the electronic camera,
wherein the plurality of correction coefficients are formed from axial luminance correction amounts representing two correction distribution characteristics changing in axial directions of two coordinate axes that form two-dimensional coordinates set on the color image, and
said luminance correction section refers to corresponding axial luminance correction amounts in units of coordinate axes on the basis of coordinate positions of the pixels and sequentially generates and uses products of two obtained axial luminance correction values as the luminance correction amounts corresponding to the pixels.
1. An electronic camera apparatus with the capability of correcting luminance balance in an image signal read out from an image sensing element, said image signal representing a color image constructed by a plurality of pixels and generating a desired image from the image signal, comprising:
a luminance correction section coupled at the output of the image sensing element and operative on individual units of raw colors of said pixels, each one of said pixels each being formed from a set of predetermined units of colors and each unit of color having an analog value representing luminance information, the luminance information being discrete on a time axis, to
A) generate individual correction coefficients for each of said predetermined colors of each said pixel from a plurality of correction coefficients
B) correct white balance using corresponding luminance information in the image signal on the basis of each said correction coefficient, and
C) output a new image signal used for image generation; and
D) store the new image in a memory located within the electronic camera,
wherein said luminance correction section comprises
a first correction control section for sequentially generating a luminance correction amount corresponding to each pixel from a plurality of first correction coefficients on the basis of a clock signal synchronized with each luminance information in the image signal,
a second correction control section for sequentially generating a luminance correction amount corresponding to each pixel from a plurality of second correction coefficients on the basis of a clock signal synchronized with each luminance information in the image signal, and
a luminance correction amplification section for setting a synthesized gain as a product of a first gain corresponding to the luminance correction amount sequentially generated by said first correction control section and the luminance correction amount sequentially generated by said second correction control section to amplify the input image signal by the synthesized gain corresponding to each luminance correction amount in units of luminance information, and outputting the new image signal.
2. An apparatus according to
3. An apparatus according to
a correction control section for sequentially generating a luminance correction amount corresponding to each pixel from the plurality of correction coefficients on the basis of a clock signal synchronized with each luminance information in the image signal, and
a luminance correction amplification section for switching a gain in accordance with the luminance correction amount sequentially generated by said correction control section to amplify the input image signal by a gain corresponding to each luminance correction amount in units of luminance information, and outputting the new image signal.
4. An apparatus according to
said luminance correction section sequentially selects and uses the luminance correction amounts corresponding to the colors assigned to the pixels as the individual correction coefficients in units of pixels.
5. An apparatus according to
said luminance correction section sequentially selects and uses the luminance correction amounts corresponding to the coordinate positions of the pixels as the individual correction coefficients in units of pixels.
6. An apparatus according to
said luminance correction section sequentially selects and uses the luminance correction amounts corresponding to the coordinate regions to which the pixels belong as the individual correction coefficients in units of pixels.
7. An apparatus according to
said luminance correction section refers to corresponding axial luminance correction amounts in units of coordinate axes on the basis of coordinate positions of the pixels and sequentially generates the luminance correction amounts corresponding to the pixels from two obtained axial luminance correction values.
8. An apparatus according to
said luminance correction section refers to corresponding axial luminance correction amounts in units of coordinate axes on the basis of coordinate positions of the pixels and sequentially generates and uses sums of two obtained axial luminance correction values as the luminance correction amounts corresponding to the pixels.
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The present invention relates to an electronic camera apparatus and, more particularly, to an electronic camera apparatus for correcting the luminance level of a luminance signal obtained from an image sensing device having a color filter.
Generally, many electronic camera apparatuses called digital still cameras employ an arrangement for sensing a color image using a color filter formed on one image sensing device.
In this arrangement, an analog image signal is obtained from the image sensing device, in which a color image is represented by assigning predetermined colors to a number of pixels in advance, and pieces of luminance information with analog values representing the luminances of the pixels are discrete on the time axis.
Normally, in sensing a color image, the luminance of an obtained image signal must be corrected in accordance with the type of light source and ambient brightness.
In the electronic camera apparatus, a luminance correction amount is calculated from an image signal obtained by the image sensing device in, e.g., a test photometry mode before image sensing, and an image signal obtained later by pressing the shutter button is corrected using the luminance correction amount.
Assume a case wherein an image signal is converted into digital image data by an A/D converter and then subjected to various image processing operations. After the image signal is A/D-converted, information of details is lost by quantization. For this reason, the image quality obtained by subsequent image processing is largely influenced by the quality of original information.
Especially, a pixel with low luminance has a very small amount of information and is also greatly influenced by noise and the like. Normally, before A/D conversion, an analog signal is directly amplified to minimize damage to the information amount of such pixel with low luminance.
A color image sensed by an image sensing device 101 in the test photometry mode is input to a variable gain amplification section 102 as an image signal 111.
The image signal 111 is amplified by the gain controlled by a gain control section 103, converted into a digital signal by an A/D conversion section 104, and temporarily stored in a digital memory 105 as image data.
Image data 113 is read out from the digital memory 105. A luminance detection section 106 detects statistical luminance information such as average luminance and maximum and minimum luminance values in units of colors of the image data 113.
In accordance with the detection result from the luminance detection section 106, a control section 107 calculates a correction coefficient common to all colors. The gain of the variable gain amplification section 102 is set by the gain control section 103 on the basis of the correction coefficient.
When an image signal is obtained indoors under an incandescent lamp, the white balance of the obtained color image is bad, and the luminance of blue (B) tends to extremely lower, as shown in
For example, it should be balanced as shown in
In this case, the control section 107 calculates a correction coefficient that corrects with which the luminance of blue (B) has an appropriate value to some degree, and a corresponding gain is set by the gain control section 103.
In the subsequent image sensing mode, pieces of luminance information contained in the image signal 111 from the image sensing device 101 are amplified by the gain based on the correction coefficient at the same magnification for all colors, as shown in
Then, as described above, the image signal is converted into a digital signal by the A/D conversion section 104 and temporarily stored in the digital memory 105 as new image data.
After that, new image data 113 is read out from the digital memory 105, and the statistical luminance information of the new image data 113 is detected by the luminance detection section 106 in the same way as described above.
Accordingly, the control section 107 determines whether image processing is necessary and calculates parameters therefor. An image processing section 108 executes predetermined image processing for the new image data 113, e.g., processing of further amplifying the luminance of blue (B).
With this processing, image data color-balanced to some extent is generated, as shown in
The image processing section 108 also performs, other processing such as color correction, contour extraction, and compression.
However, such a conventional electronic camera apparatus has the following problems because the variable gain amplifier provided on the output side of the image sensing device amplifies the image signal obtained from the image sensing device by the same gain for all colors and all pixel positions.
Referring to
For example, referring to
Hence, the luminance distribution shifts to the high luminance side. In addition, all the luminance values exceeding the input range become the highest luminance value (1.0), and the original luminance information is lost, resulting in an image with poor quality.
Normally, in the optical system used to focus light to the image sensing device, light at corners is attenuated as compared to the central portion due to the Cosine Fourth Law or shading, as known as vignetting.
However, the variable gain amplification section 102 of the conventional electronic camera apparatus shown in
Such vignetting may be corrected by filter processing by the image processing section on the output side. In fact, vignetting tends not to be corrected because the processing takes a time and consumes power.
The present invention has been made to solve the above problems, and has as its object to provide an electronic camera apparatus capable of obtaining an image with appropriate luminance balance without degrading the image quality.
In order to achieve the above object, according to the present invention, there is provided an electronic camera apparatus for reading out, from an image sensing device, an image signal which represents a color image constructed by a number of pixels to which predetermined colors are assigned and has pieces of luminance information with analog values representing luminances of the pixels, the luminance information being discrete on a time axis, and generating a desired image from the image signal, comprising a luminance correction section for generating individual correction coefficients from a plurality of correction coefficients in units of pixels, correcting corresponding luminance information in the image signal on the basis of each correction coefficient, and outputting a new image signal used for image generation.
The present invention will be described next with reference to the accompanying drawings.
Referring to
A luminance detection section 6 detects, from an image signal 5B amplified by the luminance correction section 10, statistical luminance information such as the average luminance value and maximum and minimum luminance values in units of colors and, additionally, commonly for all colors. A control section 7 calculates a luminance correction coefficient for each pixel and, additionally, that common to all pixels on the basis of the statistical luminance information detected by the luminance detection section 6.
An A/D conversion section 8 converts the image signal 5B into a digital signal. A digital storage section 9 stores the digital image signal converted by the A/D conversion section 8 as image data.
The image signal 5A obtained from the image sensing device 5 is generally called a color interleaved signal. This image signal represents a color image constructed by a number of pixels to which predetermined colors (e.g., red, green, and blue: RGB) are assigned in advance. In this image signal, pieces of luminance information with analog values representing the luminances of the pixels are discrete on the time axis.
A clock signal CLK is synchronized with each luminance value in the image signal 5A.
An image processing section using, e.g., a DSP may be connected to the output side of the digital storage section 9 or an analog storage section 9A as needed, as in the prior art, to perform image processing such as color correction, edge extraction, and compression for the image data read out from the storage section 9 or 9A.
The digital storage section 9 or analog storage section 9A may be constructed by a detachable storage medium.
The luminance correction section 10 will be described next with reference to
Referring to
The luminance correction amplification section 1 will be described next with reference to
Referring to
The gain switching section 11 has a plurality of capacitive elements C1 to Cn having different capacitances and arranged in parallel with respect to the image signal 5A.
Switches S11 to S1n and S21 to S2n are connected to the input and output sides of the capacitive elements C1 to Cn. These switches are ON/OFF-controlled by the switching signals φ11 to φ1n and φ21 to φ2n from the gain control section 2.
In the amplification section 12, an operational amplifier 13 and inverting amplifier 14 are serially connected.
A capacitive element C0 as a fixed capacitance component and switch S0 are parallelly connected between the inverting input (−) and the output of the operational amplifier.
Especially, the capacitance ratios of the capacitive element C0 to the capacitive elements C1 to Cn are set at 20 to 2n−1, respectively. Bits that represent desired gains by n binary digits are made to correspond to the capacitive elements C1 to Cn, respectively.
The gain control section 2 will be described next with reference to
Bits α11 to α1n, α21 to α2n, . . . αm1 to αmn corresponding to the correction coefficients α1 to αm are parallelly input to the switching control sections 21 to 2n, respectively. One of these bits is selected by a coefficient selection section 33 on the basis of the clock CLK and output as a correction coefficient α0.
On the basis of clocks φ0 and φ1 synchronized with the clock CLK, the switching signals φ11 to φ1n and φ21 to φ2n are generated by gates 31 and 32.
As the first embodiment of the present invention, a case wherein the luminance of the image signal 5A formed from an RGB color interleaved signal is corrected in units of colors, i.e., red, green, and blue (RGB) using individual correction coefficients αR, αG, and αB will be described next with reference to the accompanying drawings.
Assume that although the object color temperatures of all of red, green, and blue (RGB) are balanced, as shown in
In this case, to obtain white balance as shown in
In actual image sensing, images are continuously received from the image sensing device 5, as in a general electronic camera.
The gain of the luminance correction section 10 is set at an appropriate value (e.g., 1×), and an image is obtained. When the shutter button is pressed, the correction coefficients are calculated by the control section 7 on the basis of statistical luminance information detected by the luminance detection section 6 from the image signal of a preceding (e.g., immediately preceding) image.
When the image signal 5A is expressed as a two-dimensional plane, i.e., a color frame, a checkerboard pattern of RGB is normally formed, as shown in
Hence, the individual correction coefficients for the respective colors need be ON/OFF-controlled in accordance with the color layout, as shown in
Referring to
The coefficient selection section 33 also has a switching section (MUX) 34B for selectively outputting the output from the switching section 34A and a green correction coefficient αGi on the basis of the clock CLK synchronized with each pixel.
The coefficient selection section 33 selectively outputs a color correction coefficient αKi corresponding to each pixel position represented by the clock CLK, as shown in
On the basis of the clocks φ0 and φ1, the switching signals φ11 and φ21 are generated by the gates 31 and 32.
A flip-flop (FF) 35 is provided to hold the clock CLK for only a period corresponding to one pixel and output the clock.
The signal Line can be generated by counting the clocks CLK corresponding to the number of pixels of one line.
As shown in the timing chart of
The gain switching section 11 of the luminance correction amplification section 1 turns on/off the switches S11 to S1n and S21 to S2n in accordance with the switching signals φ11 to φ1n and φ21 to φ2n representing the correction coefficient αR.
Of the capacitive elements C1 to Cn, only capacitive elements whose switches S11 to S1n are turned on are charged in correspondence with the amplification voltage of the image signal 5A, i.e., the pixel level of red pixels corresponding to the R section.
After that, only charges in the capacitive elements whose switches S21 to S2n are ON are applied to the amplification section 12. As a result, the signal is amplified by the capacitance ratio of the capacitive elements whose switches S21 to S2n are ON to the capacitive element C0 and output.
In this way, the correction coefficients αRi, αGi, and αBi corresponding to RGB colors are selected by the gain control section 2 in the R, G, and B sections corresponding to the pixels. In accordance with the correction coefficient, the image signal 5A is amplified by the luminance correction amplification section 1 in units of colors using individual gains, so the image signal 5B with corrected white balance is obtained.
Hence, unlike the prior art in which the image signal is amplified using a gain common to all colors, the image signal can be amplified in units of colors using appropriate gains without saturating a color with satisfactory luminance, and an image with appropriate luminance can be obtained without degrading the image quality.
In addition, since the luminance of an analog image signal is corrected, the signal can be processed at a high speed with a small circuit scale, and power consumption can also be reduced, as compared to a case wherein data processing done in digital domain by an image processing section.
As an expansion example of such light source correction, the scene of an image may be estimated using various types of statistical luminance information, and the image signal may be corrected in units of colors using correction coefficients optimum to the scene.
For example if it is determined a scene at the sunset, the correlation coefficients of the respective colors are set not to reduce reddishness too much, thereby adjusting white balance without losing the feature of the scene.
An example of light source correction has been described above. However, the present invention is not limited to this.
For example, as shown in
More specifically, when the image signal 5A with characteristics shown in
As shown in
More specifically, when the image signal 5A with characteristics shown in
As is apparent from the above description, it can be expressed that the luminance correction section 10 of the present invention performs processing as shown in
More specifically, a correction coefficient αK in units of pixels contained in the image signal 5A is represented by the sum of products of correction coefficients αR, αG, and αB corresponding to the respective colors and switch coefficients SR, SG, and SB which are “1” only when colors corresponding to the pixels are red, green, and blue (RGB), and “0” otherwise.
In the above description, as shown in
The luminance detection section comprises a luminance adder 61 for adding pixel values (voltage values) of a predetermined color using a switched capacitor and outputting the result, a comparator 62 for comparing a sum output 6A from the luminance adder 61 with a threshold value VTH, and a counter 63 for counting a comparison output 6B from the comparator 62 and outputting a counter output 6C to the control section 7 as an average luminance value.
Switches S61 and S62 of the luminance adder 61 are alternately turned on without any overlapping in a period corresponding to pixels of a predetermined color of the image signal 5B, thereby storing, in a capacitive element C60, charges stored in a capacitive element C61.
With this operation, the sum output 6A gradually increases, as shown in
In this case, the ratio of an increase in the sum output 6A to the threshold value VTH (a change in the counter output 6C), i.e., the resolution is determined by a capacitance ratio STEP of the capacitive element C60 to the capacitive element C61.
Since statistical luminance information is directly detected from the analog image signal, the statistical luminance information of desired color pixels or all pixels can be accurately detected at a high speed without using any A/D converter.
In the above description, the correction coefficient α of the gain control section 2 is calculated and set by the control section 7 in units of image signals 5A obtained by the image sensing device 5. However, for fixed luminance correction in the apparatus, a fixed correction coefficient may be used.
For example, a correction coefficient used for sensitivity correction of the image sensing device 5 or sensitivity correction for vignetting by an optical system (to be described later) may be obtained by measurement in advance and registered in, e.g., a ROM.
The second embodiment of the present invention in which the present invention is applied to light attenuation correction for vignetting of an optical system will be described next with reference to the accompanying drawings.
In the optical system arranged on the input side of an image sensing device 5, vignetting as shown in
Generally, when the angle that is made by a center O of an image obtained by the image sensing device and a point P apart from the center O and viewed from a point R apart from the center O in the vertical direction by a distance D is θ, the light attenuation amount at the point P is represented by COSk θ, and the value k normally has a numerical value within the range of 1 to 4.
Correction coefficients for such a light attenuation amount cannot be prepared for all pixels.
In the present invention, as shown in
First, as shown in
A correction coefficient αP(x,y) at pixel positions x and y is obtained from the product of correction coefficients in the two axial directions.
In this case, as shown in
Referring to
The corresponding correction coefficient αX(x) is selected from the correction coefficients αX(1) to αX(w) by a switching section (MUX) 37X on the basis of the coordinate value x and the corresponding correction coefficient αY(y) is selected from the correction coefficients αY(1) to αY(h) by a switching section (MUX) 37Y on the basis of the coordinate value y. These correction coefficients are added by an adder 39.
The correction coefficient αP(x,y) corresponding to the coordinate positions of each pixel is calculated. On the basis of clocks φ0 and φ1, switching signals φ1i and φ2i are generated by gates 31 and 32, respectively.
Hence, switching signals φ11 to φ1n and φ21 to φ2n corresponding to the correction coefficient αP(x,y) for correcting vignetting are output to a luminance correction amplification section 1 in units of pixel positions x and y. An image signal 5A is amplified using individual gains in units of pixel positions, and an image signal 5B with corrected vignetting is obtained.
With this arrangement, the image signal can be amplified by appropriate gains in units of pixel positions, and an image with appropriate luminance can be obtained without degrading the image quality.
In addition, since luminance of an analog image signal is corrected, the signal can be processed at a high speed with a small circuit scale, and power consumption can also be reduced, as compared to a case wherein data processing done in digital domain by an image processing section.
In the above description, the correction coefficients αX(1) to αX(w) and αY(1) to αY(h) individually obtained in advance in units of pixel positions x and y are used. However, correction coefficients obtained in advance in units of predetermined pixel ranges may be used.
First, as shown in
The desired pixel positions x and y are converted into pixel ranges x′ and y′. A correction coefficient αP(x′,y′) in the pixel ranges x′ and y′ is obtained from the product of correction coefficients in the two axial directions, as the correction coefficient αP(x,y) at the pixel positions x and y.
In this case as well, as described above, as shown in
As described above, since the correction coefficients on the X- and Y-axis sides are used in units of pixel ranges on the image, the storage capacity necessary for storing correction coefficients can be decreased.
The switching control section in the gain control section 2 for realizing this operation is the same as that shown in
In the second embodiment, as an example of luminance correction for vignetting by the optical system, luminance correction for vignetting having the distribution COSk θ from the frame center has been described. However, the present invention is not limited to this.
For example, when an optical system including a prism or the like is used, light attenuation, i.e., degradation in sensitivity has another distribution characteristic.
A different sensitivity degradation distribution may occur due to a factor other than the optical system.
However, when the light attenuation distribution or sensitivity degradation distribution can be represented by arithmetic expressions shown in
As a method of performing luminance correction for another light attenuation distribution or sensitivity degradation distribution in units of regions, the average luminance of each color (RGB) of individual regions of an image may be regarded as a sensitivity degradation distribution, and on the basis of the distribution, individual correction coefficients may be set in units of regions and used for luminance correction.
For example, for an image obtained from the image sensing device in advance, the average luminance of each color is detected in units of regions.
A region whose luminance Y exhibits the largest value is assumed as a white region.
Y=0.3R+0.59G+0.11B
Luminances of the remaining regions are corrected in a similar way using correction coefficients for correcting the average luminance of each color actually obtained in the white region to white.
The luminance is corrected in all regions such that the region with the largest average luminance value becomes the white region, so appropriate white balance can be relatively easily obtained.
Instead of correcting luminances of the remaining regions with reference to the white region, luminance of each region may be corrected using an appropriate reference.
For example, in the average luminance of all colors (RGB) in an arbitrary region, a greater part of luminance distribution is shifted to the upper or lower side of a desired range (e.g., the input range of the A/D conversion section) used in subsequent processing, individual correction coefficients with which a greater part of luminance distribution falls within the range are used to correct luminance of the region.
As an arrangement for correcting luminance of an image signal on the basis of correction coefficients individually set in units of regions, a switching control section 2i as shown in
Referring to
A corresponding correction coefficient αA(x′,y′) is selected from individual correction coefficients αA(1,1) to αA(ah,aw) by the switching section (MUX) 37X on the basis of the coordinate values x′ and y′ in units of regions. On the basis of the clocks φ0 and φ1, the switching signals φ1i and φ2i are generated by the gates 31 and 32, respectively.
Hence, switching signals φ11 to φ1n and φ21 to φ2n corresponding to the correction coefficient αA(x′,y′) for individually correcting luminance of each region are output to the luminance correction amplification section 1. The image signal 5A is amplified by a corresponding gain, and the image signal 5B corrected by individual correction coefficient in units of regions is obtained.
In this case, the reference of average luminance corresponding to a desired range used in subsequent processing, i.e., reference average luminance may be set, and correction coefficients corresponding to the regions may be calculated such that the average luminance of each region falls within the range between the maximum and minimum values of the reference average luminance.
Alternatively, conversion characteristics for performing the same calculation processing as described above may be stored as a table. The average luminance of each region may be input to read out an optimum correction coefficient from the table.
As described above, since luminance is corrected in units of regions using individual correction coefficients, the desired range, i.e., the dynamic range of the electronic camera apparatus can be effectively used in units of regions, and a high-quality image can be obtained.
Even for a region such as shade in a fine day, which has luminance much lower than that of other regions, details can be reproduced without any influence on the luminance distribution of other regions.
In setting individual correction coefficients in units of regions, the maximum correction width may be suppressed within a range to some degree.
In this case, a prominent value is not set only for the correction coefficient in an arbitrary region, the sense of incompatibility due to the luminance difference at the boundary between the region and adjacent regions in the periphery is reduced, and an image signal with a higher quality can be generated.
In the above example, luminance is corrected on the basis of the average luminance of all colors (RGB) obtained in units of regions. This method may be combined with the above-described first embodiment to individually detect the average luminance of each color in units of regions and correct the luminance in units of colors in each region on the basis of the average luminance.
With this arrangement, the desired range, i.e., the dynamic range of the electronic camera apparatus can be effectively used in units of colors in each region, and a high-quality image can be obtained.
The luminance correction section 10 of the present invention can be located at any position as far as it is located between the image sensing device 5 and an A/D conversion section 8 or between the image sensing device 5 and an analog storage section 9A.
When a correlated double sampling (CDS) circuit is connected to the output side of the image sensing device 5 to remove reset noise generated in the CCD charge detection section or 1/f noise generated in the CCD output stage, the luminance correction section 10 of the present invention may be constructed using the operational amplifier in the CDS circuit.
In the above description, the present invention is individually applied as the first or second embodiment. However, the two embodiments may be simultaneously applied.
Referring to
In this case, the luminance correction section 10B corresponding to the second embodiment is connected in series with the luminance correction section 10A corresponding to the first embodiment.
The arrangement of a luminance correction amplification section 1A and luminance correction amplification section 1B is the same as that of the luminance correction amplification section 1 described with reference to
As a gain control section 2A, the switching control section 2i described with reference to
Referring to
The gain switching sections 11A and 11B have the same arrangement as that of the above-described gain switching section 11 shown in
In this case, capacitive elements of the gain switching sections 11A and 11B are selected on the basis of correction coefficients selected by the gain control sections 2A and 2B. Charges stored in the selected capacitive elements are added and transferred to the capacitive element of an amplification section 12.
As a consequence, the image signal 5A is amplified by a gain corresponding to the product of the two correction coefficients selected by the gain control sections 2A and 2B.
When different luminances are serially corrected, as shown in
When luminance correction is performed at once, as shown in
As has been described above, according to the present invention, individual correction coefficients are generated from a plurality of correction coefficients in units of pixels, and each luminance information corresponding to the pixel in the image signal is corrected on the basis of the correction coefficient.
Since a new image signal in which luminance information arranged in units of pixels are individually corrected is generated, an image with appropriate luminance balance can be obtained without degrading the image quality, unlike the prior art in which luminances of pixels are corrected using one correction coefficient.
For example, when, using correction coefficients in units of pixel colors, luminances are corrected in units of pixels using correction coefficients of colors assigned to the pixels, light source correction or white balance correction optimum to the image can be performed.
In addition, when, using correction coefficients in units of coordinate positions, luminances are corrected in units of pixels using correction coefficients corresponding to the pixel positions, vignetting by the optical system can be corrected without degrading the image quality.
Kitagawa, Shuji, Sasai, Toshihiro
Patent | Priority | Assignee | Title |
7265785, | Jul 25 2002 | Godo Kaisha IP Bridge 1 | Imaging apparatus and method that provide high resolution under low illumination without substantial S/N degradation |
7388610, | Aug 16 2002 | Qualcomm Incorporated | Techniques of modifying image field data by extrapolation |
7391450, | Aug 16 2002 | Qualcomm Incorporated | Techniques for modifying image field data |
7408576, | Aug 16 2002 | Qualcomm Incorporated | Techniques for modifying image field data as a function of radius across the image field |
7436439, | Jun 14 2002 | Casio Computer Co., Ltd. | Image pickup apparatus, gain control method, and gain control program, which sequentially set gain values in a gain adjusting circuit to select a gain value to be set in another gain adjusting circuit to maintain white balance |
7551207, | Aug 26 2003 | Casio Computer Co., Ltd. | Image pickup apparatus, white balance control method, and white balance control program |
7634152, | Mar 07 2005 | HEWLETT-PACKARD DEVELOPMENT COMPANY, L P | System and method for correcting image vignetting |
7656458, | Jul 02 2003 | Nikon Corporation | Color photographing device |
7692700, | Mar 04 2003 | Gula Consulting Limited Liability Company | Vignetting compensation |
7755671, | Apr 23 2007 | HEWLETT-PACKARD DEVELOPMENT COMPANY, L P | Correcting a captured image in digital imaging devices |
7817196, | Aug 16 2002 | Qualcomm Incorporated | Techniques of modifying image field data by extrapolation |
7834921, | Aug 16 2002 | Qualcomm Incorporated | Compensation techniques for variations in image field data |
7907195, | Aug 16 2002 | Qualcomm Incorporated | Techniques for modifying image field data as a function of radius across the image field |
8031255, | Jan 09 2007 | FUJIFILM Corporation | Image capturing device with field limiting parts and method of capturing an image using field limiting parts |
8218037, | Aug 16 2002 | Qualcomm Incorporated | Techniques of modifying image field data by extrapolation |
9654742, | Nov 30 2012 | SAFETY MANAGEMENT SERVICES, INC | System and method of automatically determining material reaction or sensitivity using images |
9800793, | Jan 14 2016 | Realtek Semiconductor Corp. | Method for generating target gain value of wide dynamic range operation |
Patent | Priority | Assignee | Title |
5196923, | May 25 1989 | Canon Kabushiki Kaisha | Automatic image signal correcting device |
5432550, | Mar 23 1993 | DAEWOO ELECTRONICS CO , LTD | Camcorder equipped with a function for correcting brightness on the sides of a screen |
5504524, | Oct 13 1994 | VLSI Vision Limited; VLSI VISION LIMITED AVIATION HOUSE, 31 PINKHILL | Method and apparatus for controlling color balance of a video signal |
5530474, | Sep 05 1991 | Canon Kabushiki Kaisha | White balance correction device with correction signal limiting device |
5534916, | Apr 05 1994 | Ricoh Company, Ltd. | Digital electronic still camera operable in a text mode for photographing a bilevel image |
5606392, | Jun 28 1996 | Intellectual Ventures Fund 83 LLC | Camera using calibrated aperture settings for exposure control |
5644359, | Apr 03 1995 | Canon Kabushiki Kaisha | Image input apparatus having a white balance correction means and a method of inputting an image using the image input apparatus |
5668596, | Feb 29 1996 | Eastman Kodak Company | Digital imaging device optimized for color performance |
5712682, | Apr 26 1996 | Intel Corporation | Camera having an adaptive gain control |
5737017, | Oct 09 1992 | Canon Kabushiki Kaisha | Color image pickup apparatus having a plurality of color filters |
5870505, | Mar 14 1996 | Intellectual Ventures I LLC | Method and apparatus for pixel level luminance adjustment |
5936668, | Oct 02 1995 | Hoya Corporation | Color image display device |
6526181, | Jan 27 1998 | Apple Inc | Apparatus and method for eliminating imaging sensor line noise |
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Feb 14 2000 | KITAGAWA, SHUJI | NUCORE TECHNOLOGY INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 010644 | /0446 | |
Feb 23 2000 | NuCORE Technology, Inc. | (assignment on the face of the patent) | / | |||
Sep 17 2007 | NUCORE TECHNOLOGY INC | Mediatek USA Inc | CHANGE OF NAME SEE DOCUMENT FOR DETAILS | 020555 | /0847 | |
Nov 18 2009 | Mediatek USA Inc | Mediatek Singapore Pte Ltd | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 023546 | /0868 |
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